Three scientists who studied the workings of organisms’ inner circadian clocks have won the 2017 Nobel Prize in Physiology or Medicine. Jeffrey Hall and Michael Rosbash, both at Brandeis University in Waltham, Massachusetts, will split the award of 9 million Swedish kronor (US$1.1 million) with Michael Young at Rockefeller University in New York City.
Beginning in the 1980s, the three researchers isolated and characterized a gene in fruit flies, period, that encodes a protein that builds up each night, only to be broken down the following day. In subsequent work, the trio, as well as other scientists, unpicked the molecular regulation of the period gene (and the protein that it encodes, called PER) and identified additional components of the circadian clock.
All multicellular organisms possess circadian clocks, and human versions of the genes that comprise their clocks have been implicated in sleeping disorders and other medical conditions.
Rosbash, Hall and Young have been collecting awards together for the past five years.says Herman Wijnen, who studies circadian clocks at the University of Southampton, UK and was a postdoc in Young’s lab. “This has been one that people have been looking out for,” he says. “It’s been settled in the scientific community that this is the trio.”
But Young says he was so stunned by the news that he could barely get his shoes on the morning he found out. “I’d go and I’d pick up the shoes, and then I’d realize I need the socks,” he said during a press conference. “And then I realized I needed to put my pants on first.” The award took Rosbash by surprise too, says Thomas Perlmann, secretary of the Nobel Assembly, which selects the prizewinners. “I first got hold of Michael Rosbash, and he was silent,” says Perlmann. “And then he said, ‘you are kidding me’.”
The work has its roots in genetic screens performed by physicist and molecular biologist Seymour Benzer and geneticist Ronald Konopka, who together found fruit-fly mutants with abnormal hatching rhythms. (Benzer died in 2007; Konopka in 2015.) At the time, the idea that behaviour could have a genetic basis was controversial, says Wijnen. Years later, two teams — Young leading one, Hall and Rosbash working together to lead another — would clone the genes responsible. “That really changed the situation,” says Wijnen. “Since then, it has become clear how conserved this system is and how conceptually it could work.”
The competition between the two teams — each with ambitions to be first to identify the gene — was initially intense, says Charalambos Kyriacou, a behavioural geneticist at the University of Leicester, UK, who worked with Hall in the late 1970s. “As they got older they mellowed,” he says. “They’re all good buddies now.”
Subsequent work detailed how abundance of the PER protein peaks at night and then declines during the day. Researchers gradually pieced together a model in which the accumulation of PER serves as a signal that represses expression of the gene that encodes it. This type of negative feedback loop would become a prevailing theme in the study of circadian rhythms, as researchers identified additional loops and clock proteins over the years.
Joseph Takahashi at the University of Texas Southwestern Medical Center in Dallas and others extended the work from fruit flies to mammals, and showed that the system is remarkably conserved across species. Researchers have since tied the circadian clock to many aspects of mental and physical well-being. “We expose ourselves to inappropriate light, we travel across time zones, we do shift work,” says Wijnen. “And all of that is negatively impacting our health.”
- Journal name:
- Date published: